Transcriptomic Analysis of Immune Tolerance Induction in NOD Mice Following Oral Vaccination with GAD65-Lactococcus lactis.

Background: Type 1 diabetes (T1D) is an autoimmune disorder characterized by destruction of insulin-producing β-cells. While conventional insulin therapy manages hyperglycemia, it fails to halt autoimmunity. Oral immunotherapy targeting autoantigens like GAD65 offers potential for antigen-specific tolerance; however, its efficacy is limited by gastrointestinal degradation and poor mucosal uptake. Lactococcus lactis (L. lactis), a food-grade delivery vector, enables sustained antigen release and intestinal tract immune modulation, yet the differential transcriptomic mechanisms underlying mucosal versus systemic immune responses remain uncharacterized.

Methods: Non-obese diabetic (NOD) mice were randomized into control and GAD65 groups, receiving oral PBS or the GAD65 recombinant L. lactis vaccine, respectively. Fasting blood glucose was monitored weekly. GAD65-specific IgA and IgG, along with immune tolerance-related factors, were quantified using ELISA. Lymphocyte subsets were analyzed by flow cytometry, alongside RNA sequencing and transcriptional profiling.

Results: The study demonstrated that the orally administered GAD65-L. lactis vaccine could significantly induce GAD65-specific IgA antibody and TGF-β cytokine and alleviate hyperglycemia and diabetes symptoms in NOD mice. Our study facilitated the induction of GAD65-specific regulatory T cells within both intestinal lamina propria lymphocytes (LPLs) and splenic lymphocytes. Notably, antigen-specific tolerance was mainly observed in intestinal LPLs. Crucially, the immune responses elicited by the vaccine demonstrated significant disparities between intestinal LPLs and splenic lymphocytes, with intestinal LPLs exhibiting unique local immune tolerance transcriptomic profiles.

Conclusions: Our findings have enhanced the comprehension of the mechanisms by which oral vaccines influence the interplay between mucosal and systemic immune responses, thereby establishing a foundational framework for the design of oral vaccines. This understanding is instrumental in advancing antigen-specific immune tolerance strategies for autoimmune diseases such as Type 1 Diabetes (T1D).